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/*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*
TODO:
at this point:
- complete the set stereo_mode verb.
- find a way to tell the service which i2c chanel is used.
- separate the functions of driver from the verbs by creating new c file.
- find a way of monitoring the quality of tuning and correct it time by time.
- use Interupt for getting RDS data
*/
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <stdbool.h>
#include <string.h>
#include <unistd.h>
#include <glib.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <sys/ioctl.h>
#include <linux/i2c-dev.h>
#include <linux/i2c.h>
#include <stdarg.h>
#include <error.h>
#include <gst/gst.h>
#include <time.h>
//#include <json-c/json.h>
//#include <gst/gst.h>
#include <afb/afb-binding.h>
#include <pthread.h>
#include "radio_impl.h"
#include "tef665x.h"
#define I2C_ADDRESS 0x64
#define I2C_DEV "/dev/i2c-3"
#define VERSION "0.1"
#define TEF665x_CMD_LEN_MAX 20
#define SET_SUCCESS 1
#define TEF665X_SPLIT_SIZE 24
#define TEF665x_REF_CLK 9216000 //reference clock frequency
#define TEF665x_IS_CRYSTAL_CLK 0 //crstal
#define TEF665x_IS_EXT_CLK 1 //external clock input
#define High_16bto8b(a) ((uint8_t)((a) >> 8))
#define Low_16bto8b(a) ((uint8_t)(a))
#define Convert8bto16b(a) ((uint16_t)(((uint16_t)(*(a))) << 8 |((uint16_t)(*(a+1)))))
#define GST_PIPELINE_LEN 256
const uint8_t tef665x_patch_cmdTab1[] = {3, 0x1c,0x00,0x00};
const uint8_t tef665x_patch_cmdTab2[] = {3, 0x1c,0x00,0x74};
const uint8_t tef665x_patch_cmdTab3[] = {3, 0x1c,0x00,0x75};
typedef struct {
char *name;
uint32_t min;
uint32_t max;
uint32_t step;
} band_plan_t;
typedef struct{
radio_scan_callback_t callback;
radio_scan_direction_t direction;
void* data;
}scan_data_t;
typedef struct rds_data
{
bool Text_Changed;
bool TrafficAnnouncement;
bool TrafficProgram;
bool Music_Speech;
uint32_t Alternative_Freq[25];
uint8_t Alternative_Freq_Counter;
uint8_t Num_AlterFreq;
uint16_t PICode;
uint8_t DI_Seg;
uint8_t PTY_Code;
uint8_t Year;
uint8_t Month;
uint8_t Day;
uint8_t Hour;
uint8_t Min;
uint8_t PTYN_Size;
uint8_t raw_data[12];
char PS_Name[16];
char RT[128];
char PTYN[16];
} rds_data_t;
//thread for handling RDS and Mutex
pthread_t rds_thread;
rds_data_t RDS_Message;
pthread_mutex_t RDS_Mutex;
station_quality_t quality;
//Threads for handling Scan
pthread_t scan_thread;
pthread_mutex_t scan_mutex;
char _Temp[64]={0};
static band_plan_t known_fm_band_plans[5] = {
{ .name = "US", .min = 87900000, .max = 107900000, .step = 200000 },
{ .name = "JP", .min = 76000000, .max = 95000000, .step = 100000 },
{ .name = "EU", .min = 87500000, .max = 108000000, .step = 50000 },
{ .name = "ITU-1", .min = 87500000, .max = 108000000, .step = 50000 },
{ .name = "ITU-2", .min = 87900000, .max = 107900000, .step = 50000 }
};
static band_plan_t known_am_band_plans[1] = {
{ .name = "W-ASIA", .min = 522000, .max = 1620000, .step = 9000 }
};
static unsigned int fm_bandplan = 2;
static unsigned int am_bandplan = 0;
static bool corking = false;
static bool present = false;
static bool scanning = false;
// stream state
static GstElement *pipeline;
static bool running;
uint32_t AlterFreqOffset=0;
static void (*freq_callback)(uint32_t, void*);
static void (*rds_callback) (void*);
static void *freq_callback_data;
int tef665x_set_rds (uint32_t i2c_file_desc);
#define DEBUG 0
#if DEBUG == 1
#define _debug(x, y) printf("function: %s, %s : %d\n", __FUNCTION__, #x, y)
#else
#define _debug(x, y)
#endif
static uint32_t file_desc;
static radio_band_t current_band;
static uint32_t current_am_frequency;
static uint32_t current_fm_frequency;
static void tef665x_scan_stop (void);
static void tef665x_set_frequency (uint32_t);
static void tef665x_search_frequency (uint32_t);
static uint32_t tef665x_get_min_frequency (radio_band_t);
static uint32_t tef665x_get_max_frequency (radio_band_t);
static uint32_t tef665x_get_frequency_step (radio_band_t);
static station_quality_t *tef665x_get_quality_info (void);
static gboolean handle_message(GstBus *bus, GstMessage *msg, __attribute__((unused)) void *ptr)
{
GstState state;
if (GST_MESSAGE_TYPE(msg) == GST_MESSAGE_REQUEST_STATE) {
gst_message_parse_request_state(msg, &state);
if (state == GST_STATE_PAUSED)
corking = true;
else if (state == GST_STATE_PLAYING)
corking = false;
}
return TRUE;
}
static int tef665x_set_cmd(int i2c_file_desc, TEF665x_MODULE module, uint8_t cmd, int len, ...)
{
int i, ret;
uint8_t buf[TEF665x_CMD_LEN_MAX];
uint16_t temp;
va_list vArgs;
va_start(vArgs, len);
buf[0] = module; //module, FM/AM/APP
buf[1] = cmd; //cmd, 1,2,10,...
buf[2] = 0x01; //index, always 1
for(i = 3; i < len; i++)
{
temp = va_arg(vArgs,int);
buf[i++] = High_16bto8b(temp);
buf[i] = Low_16bto8b(temp);
}
va_end(vArgs);
ret = write(i2c_file_desc, buf, len);
temp = (ret == len) ? 1 : 0;
_debug("return value", temp);
return temp;
}
static int tef665x_get_cmd(int i2c_file_desc, TEF665x_MODULE module, uint8_t cmd, uint8_t *receive, int len)
{
uint8_t temp;
uint8_t buf[3];
int ret;
buf[0]= module; //module, FM/AM/APP
buf[1]= cmd; //cmd, 1,2,10,...
buf[2]= 1; //index, always 1
write(i2c_file_desc, buf, 3);
ret = read(i2c_file_desc, receive, len);
temp = (ret == len) ? 1 : 0;
_debug("return value", temp);
if(temp==0)
AFB_ERROR("Error Number: %d: %s",errno,strerror(errno));
return temp;
}
/*
module 64 APPL
cmd 128 Get_Operation_Status | status
index
1 status
Device operation status
0 = boot state; no command support
1 = idle state
2 = active state; radio standby
3 = active state; FM
4 = active state; AM
*/
static int appl_get_operation_status(int i2c_file_desc ,uint8_t *status)
{
uint8_t buf[2];
int ret;
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_APPL,
TEF665X_Cmd_Get_Operation_Status,
buf, sizeof(buf));
if(ret == SET_SUCCESS)
{
*status = Convert8bto16b(buf);
_debug("return value", 1);
return 1;
}
_debug("return value", 0);
return 0;
}
static int get_operation_status(int i2c_file_desc, TEF665x_STATE *status)
{
TEF665x_STATE data;
int ret;
if(SET_SUCCESS ==(ret = appl_get_operation_status(i2c_file_desc, &data)))
{
//printk( "appl_get_operation_status1 data= %d \n",data);
_debug("got status", ret);
switch(data)
{
case 0:
_debug("status: boot", ret);
*status = eDevTEF665x_Boot_state;
break;
case 1:
_debug("status: idle", ret);
*status = eDevTEF665x_Idle_state;
break;
default:
_debug("status: active", ret);
*status = eDevTEF665x_Active_state;
break;
}
}
return ret;
}
static int tef665x_power_on(int i2c_file_desc)
{
int ret;
TEF665x_STATE status;
usleep(5000);
if(SET_SUCCESS == (ret = get_operation_status(i2c_file_desc, &status))) //[ w 40 80 01 [ r 0000 ]
{
_debug("Powered ON", ret);
}
else
{
_debug("Powered ON FAILED!", ret);
}
return ret;
}
static int tef665x_writeTab(int i2c_file_desc,const uint8_t *tab)
{
int ret;
ret = write(i2c_file_desc, tab + 1, tab[0]);
return (ret != tab[0]) ? 0 : 1;
}
static int tef665x_patch_load(int i2c_file_desc, const uint8_t *bytes, uint16_t size)
{
uint8_t buf[25]; //the size which we break the data into, is 24 bytes.
int ret, i;
uint16_t num = size / 24;
uint16_t rem = size % 24;
buf[0] = 0x1b;
usleep(10000);
for(i = 0; i < num; i++)
{
memcpy(buf + 1, bytes + (24 * i), 24);
ret = write(i2c_file_desc, buf, 25);
if(ret != 25)
{
_debug("FAILED, send patch error! in pack no", i);
return false;
}
usleep(50);
}
memcpy(buf + 1, bytes + (num * 24), rem);
ret = write(i2c_file_desc, buf, rem);
if(ret != rem)
{
_debug("FAILED, send patch error at the end!", 0);
return false;
}
usleep(50);
_debug("return value", 1);
return true;
}
static int tef665x_patch_init(int i2c_file_desc)
{
int ret = 0;
ret = tef665x_writeTab(i2c_file_desc, tef665x_patch_cmdTab1); //[ w 1C 0000 ]
if(!ret)
{
_debug("1- tab1 load FAILED", ret);
return ret;
}
ret = tef665x_writeTab(i2c_file_desc, tef665x_patch_cmdTab2); //[ w 1C 0074 ]
if(!ret)
{
_debug("2- tab2 load FAILED", ret);
return ret;
}
ret = tef665x_patch_load(i2c_file_desc, pPatchBytes, patchSize); //table1
if(!ret)
{
_debug("3- pPatchBytes load FAILED", ret);
return ret;
}
ret = tef665x_writeTab(i2c_file_desc, tef665x_patch_cmdTab1); //[ w 1C 0000 ]
if(!ret)
{
_debug("4- tab1 load FAILED", ret);
return ret;
}
ret = tef665x_writeTab(i2c_file_desc, tef665x_patch_cmdTab3); //[ w 1C 0075 ]
if(!ret)
{
_debug("5- tab3 load FAILED", ret);
return ret;
}
ret = tef665x_patch_load(i2c_file_desc, pLutBytes, lutSize); //table2
if(!ret)
{
_debug("6- pLutBytes load FAILED", ret);
return ret;
}
ret = tef665x_writeTab(i2c_file_desc, tef665x_patch_cmdTab1); //[ w 1C 0000 ]
if(!ret)
{
_debug("7- tab1 load FAILED", ret);
return ret;
}
_debug("patch loaded", ret);
return ret;
}
//Command start will bring the device into? idle state�: [ w 14 0001 ]
static int tef665x_start_cmd(int i2c_file_desc)
{
int ret;
unsigned char buf[3];
buf[0] = 0x14;
buf[1] = 0;
buf[2] = 1;
ret = write(i2c_file_desc, buf, 3);
if (ret != 3)
{
_debug("start cmd FAILED", 0);
return 0;
}
_debug("return true", 1);
return 1;
}
static int tef665x_boot_state(int i2c_file_desc)
{
int ret=0;
if(1 == tef665x_patch_init(i2c_file_desc))
{
_debug("return true", 1);
}
else
{
_debug("return value", 0);
return 0;
}
usleep(50000);
if(1 == tef665x_start_cmd(i2c_file_desc))
{
_debug("'start cmd'return true", 1);
}
else
{
_debug("return value", 0);
return 0;
}
usleep(50000);
return ret;
}
/*
module 64 APPL
cmd 4 Set_ReferenceClock frequency
index
1 frequency_high
[ 15:0 ]
MSB part of the reference clock frequency
[ 31:16 ]
2 frequency_low
[ 15:0 ]
LSB part of the reference clock frequency
[ 15:0 ]
frequency [*1 Hz] (default = 9216000)
3 type
[ 15:0 ]
clock type
0 = crystal oscillator operation (default)
1 = external clock input operation
*/
static int tef665x_appl_set_referenceClock(uint32_t i2c_file_desc, uint16_t frequency_high, uint16_t frequency_low, uint16_t type)
{
return tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_APPL,
TEF665X_Cmd_Set_ReferenceClock,
9,
frequency_high, frequency_low, type);
}
static int appl_set_referenceClock(uint32_t i2c_file_desc, uint32_t frequency, bool is_ext_clk) //0x3d 0x900
{
return tef665x_appl_set_referenceClock(i2c_file_desc,(uint16_t)(frequency >> 16), (uint16_t)frequency, is_ext_clk);
}
/*
module 64 APPL
cmd 5 Activate mode
index
1 mode
[ 15:0 ]
1 = goto �active� state with operation mode of �radio standby�
*/
static int tef665x_appl_activate(uint32_t i2c_file_desc ,uint16_t mode)
{
return tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_APPL,
TEF665X_Cmd_Activate,
5,
mode);
}
static int appl_activate(uint32_t i2c_file_desc)
{
return tef665x_appl_activate(i2c_file_desc, 1);
}
/*
module 48 AUDIO
cmd 22 set_dig_io signal, format, operation, samplerate
index
1 signal
[ 15:0 ]
digital audio input / output
32 = I²S digital audio IIS_SD_0 (input)
33 = I²S digital audio IIS_SD_1 (output)
(2) mode
0 = off (default)
1 = input (only available for signal = 32)
2 = output (only available for signal = 33)
(3) format
[ 15:0 ]
digital audio format select
16 = I²S 16 bits (fIIS_BCK = 32 * samplerate)
32 = I²S 32 bits (fIIS_BCK = 64 * samplerate) (default)
272 = lsb aligned 16 bit (fIIS_BCK = 64 * samplerate)
274 = lsb aligned 18 bit (fIIS_BCK = 64 * samplerate)
276 = lsb aligned 20 bit (fIIS_BCK = 64 * samplerate)
280 = lsb aligned 24 bit (fIIS_BCK = 64 * samplerate)
(4) operation
[ 15:0 ]
operation mode
0 = slave mode; IIS_BCK and IIS_WS input defined by source (default)
256 = master mode; IIS_BCK and IIS_WS output defined by device
(5) samplerate
[ 15:0 ] 3200 = 32.0 kHz
4410 = 44.1 kHz (default)
4800 = 48.0 kHz
*/
static int tef665x_audio_set_dig_io(uint8_t i2c_file_desc, uint16_t signal, uint16_t mode, uint16_t format, uint16_t operation, uint16_t samplerate)
{
int ret = tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_AUDIO,
TEF665X_Cmd_Set_Dig_IO,
13,
signal, mode, format, operation, samplerate);
if(ret)
{
_debug("Digital In/Out is set ", signal);
}
else
{
_debug("FAILED, return", 0);
return 0;
}
return 1;
}
/*
module 32 / 33 FM / AM
cmd 85 Set_Specials ana_out, dig_out
index
1 signal
[ 15:0 ]
analog audio output
128 = DAC L/R output
2 mode
[ 15:0 ]
output mode
0 = off (power down)
1 = output enabled (default)
*/
static int tef665x_audio_set_ana_out(uint32_t i2c_file_desc, uint16_t signal,uint16_t mode)
{
int ret = tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_AUDIO,
TEF665X_Cmd_Set_Ana_Out,
7,
signal, mode);
if(ret)
{
_debug("analog output is set to ", mode);
}
else
{
_debug("FAILED, return", 0);
return 0;
}
return 1;
}
/*
module 48 AUDIO
cmd 13 Set_Output_Source
index
1 signal
[ 15:0 ]
audio output
33 = I2S Digital audio
128 = DAC L/R output (default)
2 source
[ 15:0 ]
source
4 = analog radio
32 = i2s digital audio input
224 = audio processor (default)
240 = sin wave generator
*/
static int tef665x_set_output_src(uint32_t i2c_file_desc, uint8_t signal, uint8_t src)
{
int ret = tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_AUDIO,
TEF665X_Cmd_Set_Output_Source,
7,
signal, src);
if(ret)
{
_debug("Output is set ", signal);
}
else
{
_debug("FAILED, return", 0);
return 0;
}
return 1;
}
static int tef665x_idle_state(int i2c_file_desc)
{
TEF665x_STATE status;
//mdelay(50);
if(SET_SUCCESS == get_operation_status(i2c_file_desc, &status))
{
_debug("got operation status", 1);
if(status != eDevTEF665x_Boot_state)
{
_debug("not in boot status", 1);
if(SET_SUCCESS == appl_set_referenceClock(i2c_file_desc, TEF665x_REF_CLK, TEF665x_IS_CRYSTAL_CLK)) //TEF665x_IS_EXT_CLK
{
_debug("set the clock", TEF665x_REF_CLK);
if(SET_SUCCESS == appl_activate(i2c_file_desc))// APPL_Activate mode = 1.[ w 40 05 01 0001 ]
{
//usleep(100000); //Wait 100 ms
_debug("activate succeed", 1);
return 1;
}
else
{
_debug("activate FAILED", 1);
}
}
else
{
_debug("set the clock FAILED", TEF665x_REF_CLK);
}
}
else
{
_debug("did not get operation status", 0);
}
}
_debug("return value", 0);
return 0;
}
static int tef665x_para_load(uint32_t i2c_file_desc)
{
int i;
int r;
const uint8_t *p = init_para;
for(i = 0; i < sizeof(init_para); i += (p[i]+1))
{
if(SET_SUCCESS != (r = tef665x_writeTab(i2c_file_desc, p + i)))
{
break;
}
}
//Initiate RDS
tef665x_set_rds(i2c_file_desc);
_debug("return value", r);
return r;
}
/*
module 32 / 33 FM / AM
cmd 1 Tune_To mode, frequency
index
1 mode
[ 15:0 ]
tuning actions
0 = no action (radio mode does not change as function of module band)
1 = Preset Tune to new program with short mute time
2 = Search Tune to new program and stay muted
FM 3 = AF-Update Tune to alternative frequency, store quality
and tune back with inaudible mute
4 = Jump Tune to alternative frequency with short
inaudible mute
5 = Check Tune to alternative frequency and stay
muted
AM 3 � 5 = reserved
6 = reserved
7 = End Release the mute of a Search or Check action
(frequency is not required and ignored)
2 frequency
[ 15:0 ]
tuning frequency
FM 6500 � 10800 65.00 � 108.00 MHz / 10 kHz step size
AM LW 144 � 288 144 � 288 kHz / 1 kHz step size
MW 522 � 1710 522 � 1710 kHz / 1 kHz step size
SW 2300 � 27000 2.3 � 27 MHz / 1 kHz step size
*/
static int tef665x_radio_tune_to (uint32_t i2c_file_desc, bool fm, uint16_t mode,uint16_t frequency )
{
return tef665x_set_cmd(i2c_file_desc, fm ? TEF665X_MODULE_FM: TEF665X_MODULE_AM,
TEF665X_Cmd_Tune_To,
( mode <= 5 ) ? 7 : 5,
mode, frequency);
}
static int FM_tune_to(uint32_t i2c_file_desc, AR_TuningAction_t mode, uint16_t frequency)
{
int ret = tef665x_radio_tune_to(i2c_file_desc, 1, (uint16_t)mode, frequency);
_debug("return value", ret);
return ret;
}
static int AM_tune_to(uint32_t i2c_file_desc, AR_TuningAction_t mode,uint16_t frequency)
{
int ret = tef665x_radio_tune_to(i2c_file_desc, 0, (uint16_t)mode, frequency);
_debug("return value", ret);
return ret;
}
/*
module 48 AUDIO
cmd 11 Set_Mute mode
index
1 mode
[ 15:0 ]
audio mute
0 = mute disabled
1 = mute active (default)
*/
int tef665x_audio_set_mute(uint32_t i2c_file_desc, uint16_t mode)
{
int ret = tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_AUDIO,
TEF665X_Cmd_Set_Mute,
5,
mode);
if(ret)
{
_debug("mute state changed , mode", mode);
}
else
{
_debug("FAILED, return", 0);
return 0;
}
return 1;
}
/*
module 48 AUDIO
cmd 10 Set_Volume volume
index
1 volume
[ 15:0 ] (signed)
audio volume
-599 � +240 = -60 � +24 dB volume
0 = 0 dB (default)f665x_patch_init function: "3"t,int16_t volume)
*/
static int tef665x_audio_set_volume(uint32_t i2c_file_desc, uint16_t volume)
{
return tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_AUDIO,
TEF665X_Cmd_Set_Volume,
5,
volume*10);
}
/*
module 64 APPL
cmd 130 Get_Identification
index
1 device
2 hw_version
3 sw_version
*/
int appl_get_identification(int i2c_file_desc)
{
uint8_t buf[6];
int ret;
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_APPL,
TEF665X_Cmd_Get_Identification,
buf, sizeof(buf));
// should be completed for further use
// extracting chip versions ...
if(ret == SET_SUCCESS)
{
for(int i = 0; i<6;i++)
printf("buf[%i] = %x\n", i, buf[i]);
return 1;
}
_debug("return value", 0);
return 0;
}
//mute=1, unmute=0
int audio_set_mute(uint32_t i2c_file_desc, bool mute)
{
return tef665x_audio_set_mute(i2c_file_desc, mute);//AUDIO_Set_Mute mode = 0 : disable mute
}
//-60 � +24 dB volume
int audio_set_volume(uint32_t i2c_file_desc, int vol)
{
return tef665x_audio_set_volume(i2c_file_desc, (uint16_t)vol);
}
/*
module 64 APPL
cmd 1 Set_OperationMode mode
index
1 mode
[ 15:0 ]
device operation mode
0 = normal operation
1 = radio standby mode (low-power mode without radio functionality)
(default)
*/
static int tef665x_audio_set_operationMode(uint32_t i2c_file_desc, uint16_t mode)
{
_debug("normal: 0 standby: 1 requested", 1);
int ret = tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_APPL,
TEF665X_Cmd_Set_OperationMode,
5,
mode);
if(ret)
{
_debug("was able to set the mode", ret);
}
else
{
_debug("FAILED, return", 0);
return 0;
}
return 1;
}
//TRUE = ON;
//FALSE = OFF
static void radio_powerSwitch(uint32_t i2c_file_desc, bool OnOff)
{
tef665x_audio_set_operationMode(i2c_file_desc, OnOff? 0 : 1);//standby mode = 1
}
static void radio_modeSwitch(uint32_t i2c_file_desc, bool mode_switch, AR_TuningAction_t mode, uint16_t frequency)
{
if(mode_switch) //FM
{
FM_tune_to(i2c_file_desc, mode, frequency);
}
else //AM
{
AM_tune_to(i2c_file_desc, mode, frequency);
}
}
/*
module 32 FM
cmd 81 Set_RDS
index
1 mode
[ 15:0 ]
RDS operation mode
0 = OFF
1 = decoder mode (default), output of RDS groupe data (Block A, B, C, D)
from get_rds_status, get_rds_data FM cmd 130/131
2 restart
[ 15:0 ]
RDS decoder restart
0 = no control
1 = manual restart, starlooking for new RDS data immidiately
2 = automatic restart after tuning (default)
3 = flush, empty RDS output buffer.
3 interface
[ 15:0 ]
0 = no pin interface.
2 = data available status output; active low (GPIO feature 'DAVN')
4 = legecy 2-wire demodulator data and clock output ('RDDA' and 'RDCL')
*/
int tef665x_set_rds(uint32_t i2c_file_desc)
{
return tef665x_set_cmd(i2c_file_desc, TEF665X_MODULE_FM,
TEF665X_Cmd_Set_RDS,
9,//Total Bytes to be sent
TEF665X_Cmd_Set_RDS_mode, // default
TEF665X_Cmd_Set_RDS_autorestart, // restart after tune
0x002 // no interface
);
}
/*
* @brief Adding Alternative Frequencies to RDS Data Structure
*
* @param uint8_t* : raw data of alternative frequency (Group 0A of RDS)
* @param rds_data_t* : Pointer to RDS Data Structure
* @return void
*/
void Extract_Alt_Freqs(uint8_t* buf,rds_data_t *Rds_STU)
{
for(int Buffer_Index=6;Buffer_Index<8;Buffer_Index++)
{
if(buf[Buffer_Index]>204){
if(250>buf[Buffer_Index]&&buf[Buffer_Index]>224)
{
Rds_STU->Num_AlterFreq=buf[Buffer_Index]-224;
if(Rds_STU->Alternative_Freq_Counter == Rds_STU->Num_AlterFreq)
{
Rds_STU->Alternative_Freq_Counter = 0;
}
AlterFreqOffset=87500000;
}
else if(buf[Buffer_Index]==205)
{
AFB_ERROR("Filler Code");
}
else if(buf[Buffer_Index]==224)
{
AFB_ERROR("No AF Exists");
}
else if(buf[Buffer_Index]==250)
{
AFB_ERROR("An LF/MF Frequency Follows");
AlterFreqOffset=144000;
}
else if(buf[Buffer_Index]>250)
{
AFB_WARNING("Alternative Frequency Not Assigned");
}
}
else if(buf[Buffer_Index]>0)
{
if(AlterFreqOffset == 87500000)
{
Rds_STU->Alternative_Freq[Rds_STU->Alternative_Freq_Counter]=
buf[Buffer_Index] * 100000 + AlterFreqOffset;
Rds_STU->Alternative_Freq_Counter++;
if(Rds_STU->Alternative_Freq_Counter == Rds_STU->Num_AlterFreq)
{
Rds_STU->Alternative_Freq_Counter = 0;
}
}
else if(AlterFreqOffset == 144000)
{
Rds_STU->Alternative_Freq[Rds_STU->Alternative_Freq_Counter]=
((uint32_t)buf[Buffer_Index]) * 9000 + AlterFreqOffset;
Rds_STU->Alternative_Freq_Counter++;
if(Rds_STU->Alternative_Freq_Counter == Rds_STU->Num_AlterFreq)
{
Rds_STU->Alternative_Freq_Counter = 0;
}
}
else
{
AFB_WARNING("Alternative Frequency is not defined");
}
}
else
{
AFB_ERROR("Alternative Frequency- Not to be used");
}
}
}
/*
* @brief Checking rds error code (determined by decoder)
*
* 0 : no error; block data was received with matching data and syndrome
* 1 : small error; possible 1 bit reception error detected; data is corrected
* 2 : large error; theoretical correctable error detected; data is corrected
* 3 : uncorrectable error; no data correction possible
*
* @param Errors : Error Code of blocks A,B,C and D of RDS
* @return void
*/
void Check_RDS_Error(uint8_t Errors[])
{
for (int i=0;i<4;i++){
if(Errors[i]==1){
AFB_WARNING("RDS Block %d Reception Error; small error; possible 1 bit reception error detected; data is corrected",i+1);
}
else if(Errors[i]==2){
AFB_WARNING("RDS Block %d Reception Error; large error; theoretical correctable error detected; data is corrected",i+1);
}
else if(Errors[i]==3){
AFB_ERROR("RDS Block %d Reception Error; uncorrectable error; no data correction possible",i+1);
}
}
}
/*
* @brief Getting rds_data_t and Process its raw_data
*
* @param rds_data_t * : Pointer to latest RDS Data Structure
*/
void *Process_RDS_Words(void* rds_words){
pthread_detach(pthread_self());
rds_data_t *Rds_STU = rds_words;
uint8_t *raw_data = Rds_STU->raw_data;
int8_t group_Ver = -1;
uint8_t GType0 = 0;
bool DI_Seg = 0;
bool M_S = 0;
bool TA = 0;
//Parse 1st Section
bool DataAvailable = (raw_data[0] >> 7) & 1;
bool DataLoss = (raw_data[0] >> 6) & 1 == 1;
bool DataAvailType = (raw_data[0] >> 5) & 1 == 0;
bool GroupType = (raw_data[0] >> 4) & 1;
bool SyncStatus = (raw_data[0] >> 1) & 1;
//Parse Last Section(Error Codes)
uint8_t Error_A = raw_data[10] >> 6;
uint8_t Error_B = raw_data[10] >> 4 & 3;
uint8_t Error_C = raw_data[10] >> 2 & 3;
uint8_t Error_D = raw_data[10] & 3;
uint8_t Errors[]={Error_A,Error_B,Error_C,Error_D};
//Inform user about Error Blocks Status Codes
Check_RDS_Error(Errors);
if(Error_A==0){
//Bytes 2 and 3 are inside Block A
//raw_data[2]and raw_data[3] Contains PI Code
Rds_STU->PICode=Convert8bto16b(&raw_data[2]);
}
else{
AFB_ERROR("Error_A=%d",Error_A);
}
bool GTypeVer=GType0;
uint16_t GType=raw_data[4]>>4;
//Bytes 4 and 5 are inside Block B
if(Error_B==0){
GTypeVer=raw_data[4]>>3 & 1;
GType=raw_data[4]>>4;
Rds_STU->TrafficProgram=raw_data[4]>>2&1;
Rds_STU->PTY_Code= (raw_data[4] & 3) << 3 | raw_data[5] >> 5;
}
//Position Of Character
uint8_t CharPos=0;
//Extract Data based on Group Type values
switch (GType)
{
case 0:
{
if(Error_B==0)
{
CharPos = raw_data[5] & 3;
Rds_STU->TrafficAnnouncement = raw_data[5] >> 4 & 1;
Rds_STU->Music_Speech = raw_data[5] >> 3 & 1;
Rds_STU->DI_Seg = (raw_data[5] >> 2 & 1) * (2 ^ (3 - CharPos));
}
if(Error_C==0)
{
//Group Type 0A
if (GType==0)
{
Extract_Alt_Freqs(raw_data,Rds_STU);
}
//Group Type 0B
else
{
Rds_STU->PICode=Convert8bto16b(&raw_data[6]);
}
}
if(Error_D == 0 && Error_B == 0)
{
if(raw_data[8] != 0x7f)
{
Rds_STU->PS_Name[CharPos*2] = raw_data[8];
}
else
{
Rds_STU->PS_Name[CharPos*2] = (char)'\0';
}
if(raw_data[9] != 0x7f)
{
Rds_STU->PS_Name[CharPos*2+1] = raw_data[9];
}
else
{
Rds_STU->PS_Name[CharPos*2+1] = (char)'\0';
}
}
}
break;
case 1:
{
//Group Type 1A
if(GTypeVer == 0)
{
if(Error_D == 0)
{
Rds_STU->Day = raw_data[8] >> 3;
Rds_STU->Hour = raw_data[8] >> 3;
Rds_STU->Min = ((raw_data[8] & 7) << 2) | (raw_data[9] >> 6) ;
}
}
}
break;
case 2:
{
//Group Type 2A:
if(GTypeVer == 0)
{
uint8_t Text_pos = raw_data[5] & 15;
if(Error_B == 0 && Error_C == 0)
{
if(raw_data[6] !=0x7f && raw_data[6] != '\n')
{
Rds_STU->RT[Text_pos*4] = raw_data[6];
}
else{
Rds_STU->RT[Text_pos*4] = (char)'\0';
}
if(raw_data[7]!=0x7f&&raw_data[7]!='\n')
{
Rds_STU->RT[Text_pos*4+1] = raw_data[7];
}
else
{
Rds_STU->RT[Text_pos*4+1] = (char)'\0';
}
}
if(Error_B == 0 && Error_D == 0)
{
if(raw_data[8] != 0x7f && raw_data[8] != '\n')
{
Rds_STU->RT[Text_pos*4+2] = raw_data[8];
}
else{
Rds_STU->RT[Text_pos*4+2] = (char)'\0';
}
if(raw_data[9] != 0x7f && raw_data[9] != '\n')
{
Rds_STU->RT[Text_pos*4+3] = raw_data[9];
}
else
{
Rds_STU->RT[Text_pos*4+3] = (char)'\0';
}
}
}
//Group Type 2B:
else{
if(Error_B==0 && Error_D==0)
{
//Clear All Radio Text if flag was changed
if(raw_data[5] >> 4 & 1 != Rds_STU->Text_Changed)
{
memcpy(Rds_STU->RT, _Temp , 64);
}
uint8_t Text_pos = raw_data[5] & 15;
if(raw_data[8] != 0x7f && raw_data[8] != '\n')
{
Rds_STU->RT[Text_pos*2] = raw_data[8];
}
else{
Rds_STU->RT[Text_pos*2] = (char)'\0';
}
if(raw_data[9] != 0x7f && raw_data[9] != '\n')
{
Rds_STU->RT[Text_pos*2+1] = raw_data[9];
}
else
{
Rds_STU->RT[Text_pos*2+1] = (char)'\0';
}
}
}
}
break;
case 4:
{
//Group Type 4A
if(GTypeVer == 0)
{
if(Error_B == 0 && Error_C == 0 && Error_D == 0)
{
//Following caclulations are based on RDS Standard
uint32_t Modified_Julian_Day = ((raw_data[5] & 3) << 15) | (raw_data[6] << 7) | (raw_data[7]>>1);
int y2 = (int)((((double)Modified_Julian_Day)-15078.2)/365.25);
int m2 = (int)((((double)Modified_Julian_Day)-14956.1-((double)y2*365.25))/30.6001);
int d2 = (double)Modified_Julian_Day-14956-(int)(y2*365.25)-(int)(m2*30.6001);
int k = 0;
if(m2 == 14 || m2 == 15)
{
k = 1;
}
Rds_STU->Day = d2;
Rds_STU->Month = m2 - 1 + k * 12;
Rds_STU->Year = y2 + k;
uint8_t UTCHour = ((raw_data[7] & 1) << 4) | (raw_data[8] >> 4);
uint8_t UTCMinute = ((raw_data[8] & 15) << 2) | (raw_data[9] >> 6);
//Check Negative Offset
bool NegOff = raw_data[9] & 32;
uint8_t LocTimeOff = raw_data[9] & 31;
if(!NegOff)
{
Rds_STU->Min = UTCMinute + LocTimeOff % 2;
while(UTCMinute > 60)
{
UTCHour++;
UTCMinute = UTCMinute - 60;
}
Rds_STU->Hour = UTCHour + LocTimeOff / 2;
while(Rds_STU->Hour > 24){
Rds_STU->Hour = Rds_STU->Hour - 24;
}
}
else{
Rds_STU->Min = UTCMinute + LocTimeOff % 2;
while(UTCMinute < 0)
{
UTCHour--;
UTCMinute = UTCMinute + 60;
}
Rds_STU->Hour = UTCHour + LocTimeOff / 2;
while(Rds_STU->Hour<0)
{
Rds_STU->Hour = Rds_STU->Hour + 24;
}
}
}
}
//Group Type 4B
else
{
AFB_WARNING("Groupe Type 4B are not supported yet");
}
}
case 8:
{
AFB_WARNING("Groupe Type 8A and 8B are not supported yet");
}
case 10:
{
AFB_WARNING("Groupe Type 10A and 10B are not supported yet");
/*
if(Error_B == 0){
uint8_t pos = 0;
pos=(raw_data[5] & 1) * 4;
if(Error_C == 0){
Rds_STU->PTYN[pos] = raw_data[6];
Rds_STU->PTYN[pos+1] = raw_data[7];
Rds_STU->PTYN_Size = pos + 2;
}
if(Error_D == 0){
Rds_STU->PTYN[pos+2] = raw_data[8];
Rds_STU->PTYN[pos+3] = raw_data[9];
Rds_STU->PTYN_Size = pos + 4;
}
}
/**/
}
break;
default:
AFB_ERROR("Unsupported Group %d",GType);
break;
}
if(!DataAvailable)
{
AFB_ERROR("RDS Data is not available");
}
if(DataLoss)
{
AFB_ERROR("previous data was not read, replaced by newer data");
}
if(GroupType == 0)
{
group_Ver = 0;
}
else
{
group_Ver = 1;
}
if(!SyncStatus)
{
AFB_ERROR(" RDS decoder not synchronized; no RDS data found");
}
if(GroupType != GTypeVer)
{
AFB_ERROR("Version is not Correct?");
}
}
/*
module 32 FM
cmd 131 get RDS data
index
1 status
[ 15:0 ]
FM RDS reception status.
[15] = dta availableflag
0 = no data
1 = data available
[14] = data loss flag
0 = no data loss
1 = previose data not read, replaced by newer data.
[13] = data available type
0 = group data; continuos operation.
1 = first PI data;data with PI code following decoder sync.
[12] = groupe type.
0 = type A; A-B-C-D group (with PI code in the block A)
1 = type B; A-B-C'-D group (with PI code in the block A and C')
[ 8:0 ] reserved
2 A_Block
[ 15:0 ] = A block data
3 B_Block
[ 15:0 ] = B block data
4 C_Block
[ 15:0 ] = C block data
5 D_Block
[ 15:0 ] = D block data
6 dec error
[ 15:0 ]
error code determined by decoder
[ 15:14 ] = A block error
[ 13:12 ] = B block error
[ 11:10 ] = C block error
[ 9:8 ] = D block error
0 = no error found
1 = small error, correctable. data is corrected.
2 = larg error, correctable. data is corrected.
3 = uncorrectable error.
[ 7:0 ] = reserved.
*/
/*
* @brief Get RDS Data fron Tef-665
*
* Getting RDS Data From I2C and Calling a thread to process raw data
*
* @param i2c_file_desc : I2C File Descriptor
* @param Rds_STU : RDS Data Structure
*
*/
int tef665x_get_rds_data(uint32_t i2c_file_desc, rds_data_t *Rds_STU)
{
int ret;
uint8_t buf[12];
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_FM,
TEF665X_Cmd_Get_RDS_Data,
buf, sizeof(buf));
if(ret == 1) {
memcpy(Rds_STU->raw_data,buf,12);
pthread_t t0;
pthread_create(&t0, NULL,Process_RDS_Words ,(void *) (Rds_STU));
}
return ret;
}
void Clear_RDS_Data(rds_data_t *Rds_STU){
Rds_STU-> Text_Changed=0;
Rds_STU-> TrafficAnnouncement=0;
Rds_STU-> TrafficProgram=0;
Rds_STU-> Music_Speech=0;
Rds_STU-> DI_Seg=0;
Rds_STU-> PTY_Code=0;
Rds_STU-> Num_AlterFreq=0;
Rds_STU->PTYN_Size=0;
Rds_STU-> Day=0;
Rds_STU-> Month=0;
Rds_STU-> Year=0;
Rds_STU-> Hour=0;
Rds_STU-> Min=0;
/*memcpy(Rds_STU->Alternative_Freq,_Temp,25);/**/
for(uint8_t i=0;i<25;i++){
Rds_STU->Alternative_Freq[i]=0;
}
memcpy(Rds_STU-> PS_Name,_Temp,8);
Rds_STU-> PS_Name[0]='\0';
memcpy(Rds_STU-> RT,_Temp,64);
Rds_STU-> RT[0]='\0';
memcpy(Rds_STU-> PTYN,_Temp,8);
Rds_STU-> PTYN[0]='\0';
Rds_STU-> PICode=0;
Rds_STU->Alternative_Freq_Counter=0;
Rds_STU->PTYN_Size=0;
}
//Check if RDS is available
int tef665x_get_rds_status(uint32_t i2c_file_desc, uint16_t *status)
{
int ret = 0;
uint8_t buf[2];
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_FM,
TEF665X_Cmd_Get_RDS_Status,
buf, sizeof(buf));
if(ret == 1){
status[0] =buf[0];
status[1] =buf[1];
}
return ret;
}
static int tef665x_wait_active(uint32_t i2c_file_desc)
{
TEF665x_STATE status;
//usleep(50000);
if(SET_SUCCESS == appl_get_operation_status(i2c_file_desc, &status))
{
AFB_INFO("got status", 1);
if((status != eDevTEF665x_Boot_state) && (status != eDevTEF665x_Idle_state))
{
AFB_INFO("active status", 1);
if(SET_SUCCESS == tef665x_para_load(i2c_file_desc))
{
_debug("parameters loaded", 1);
}
else
{
_debug("parameters not loaded", 0);
return 0;
}
if(current_band == BAND_FM){
FM_tune_to(i2c_file_desc, eAR_TuningAction_Preset, current_fm_frequency / 10000);// tune to min
} else {
AM_tune_to(i2c_file_desc, eAR_TuningAction_Preset, current_am_frequency / 1000);// tune to min
}
if(SET_SUCCESS == audio_set_mute(i2c_file_desc, 1))//unmute=0
{
_debug("muted", 1);
}
else
{
_debug("not muted", 0);
return 0;
}
// //if(SET_SUCCESS == audio_set_volume(i2c_file_desc, 35))//set to -10db
// {
// _debug("set vol to", 25);
// }
// else
// {
// _debug("vol not set", 0);
// return 0;
// }
return 1;
}
}
return 0;
}
static void tef665x_chip_init(int i2c_file_desc)
{
if(1 == tef665x_power_on(i2c_file_desc)) _debug("tef665x_power_on", 1);
usleep(50000);
if(1 == tef665x_boot_state(i2c_file_desc)) _debug("tef665x_boot_state", 1);
usleep(100000);
if(1 == tef665x_idle_state(i2c_file_desc)) _debug("tef665x_idle_state", 1);
usleep(200000);
if(1 == tef665x_wait_active(i2c_file_desc)) _debug("tef665x_wait_active", 1);
//if you want to use analog output comment below command, or pass 1 to it.
if(SET_SUCCESS != tef665x_audio_set_ana_out(i2c_file_desc, TEF665X_Cmd_Set_Output_signal_dac, 0))
{
_debug("Set DAC to OFF failed", 0);
//return 0;
}
if(SET_SUCCESS != tef665x_set_output_src(i2c_file_desc, TEF665X_Cmd_Set_Output_signal_i2s,
TEF665X_Cmd_Set_Output_source_aProcessor))
{
_debug("Set output failed", 0);
//return 0;
}
//this is needed to use digital output
if(SET_SUCCESS != tef665x_audio_set_dig_io(i2c_file_desc, TEF665X_AUDIO_CMD_22_SIGNAL_i2s1,
TEF665X_AUDIO_CMD_22_MODE_voltage,
TEF665X_AUDIO_CMD_22_FORMAT_16,
TEF665X_AUDIO_CMD_22_OPERATION_slave,
TEF665X_AUDIO_CMD_22_SAMPLERATE_48K))
{
_debug("Setup i2s failed", 0);
//return 0;
}
}
static int i2c_init(const char *i2c, int state, uint32_t *i2c_file_desc)
{
int fd = 0, t;
if(state == _open)
{
fd = open(i2c, O_RDWR);
if(fd < 0)
{
_debug("could not open %s", i2c);
return fd;
}
t = ioctl(fd, I2C_SLAVE, I2C_ADDRESS);
if (t < 0)
{
_debug("could not set up slave ", 0);
return t;
}
*i2c_file_desc = fd;
}
else
{
close(*i2c_file_desc);
}
return 0;
}
static void tef665x_start(void)
{
int ret;
if(!present)
return;
_debug("file_desc ", file_desc);
audio_set_mute(file_desc, 0);
if(!running) {
// Start pipeline
ret = gst_element_set_state(pipeline, GST_STATE_PLAYING);
_debug("gst_element_set_state to play", ret);
running = true;
}
}
/*
* @brief Send_Rds_Result to rds subscribers
*
* @param rds_data_t : a rds message structure
* @return The JsonObject of rds info
*/
void *Send_Rds_Result(rds_data_t* RDS_Message){
//Kill the thread when it was over
pthread_detach(pthread_self());
json_object *ret_json;
json_object *Alternative_Freqs;
ret_json = json_object_new_object();
Alternative_Freqs=json_object_new_array();
for(uint8_t af=0 ; af<25 ; af++)
{
if(RDS_Message->Alternative_Freq[af]!=NULL&&RDS_Message->Alternative_Freq[af]!=0)
{
json_object_array_add(Alternative_Freqs,json_object_new_int(RDS_Message->Alternative_Freq[af]));
}
}
//Prepare JSon Object
json_object_object_add(ret_json, "name" , json_object_new_string(RDS_Message->PS_Name));
json_object_object_add(ret_json, "radiotext" , json_object_new_string(RDS_Message->RT));
json_object_object_add(ret_json, "alternatives" , (Alternative_Freqs));
json_object_object_add(ret_json, "minute" , json_object_new_int (RDS_Message->Min));
json_object_object_add(ret_json, "hour" , json_object_new_int (RDS_Message->Hour));
json_object_object_add(ret_json, "day" , json_object_new_int (RDS_Message->Day));
json_object_object_add(ret_json, "month" , json_object_new_int (RDS_Message->Month));
json_object_object_add(ret_json, "year" , json_object_new_int (RDS_Message->Year));
json_object_object_add(ret_json, "pi" , json_object_new_int (RDS_Message->PICode));
json_object_object_add(ret_json, "pty" , json_object_new_int (RDS_Message->PTY_Code));
json_object_object_add(ret_json, "ta" , json_object_new_int (RDS_Message->TrafficAnnouncement));
json_object_object_add(ret_json, "tp" , json_object_new_int (RDS_Message->TrafficProgram));
json_object_object_add(ret_json, "ms" , json_object_new_int (RDS_Message->Music_Speech));
//Send JsonObject to rds Subscribers
if(rds_callback){
rds_callback(ret_json);
}
return ret_json;
}
/*
* @brief Create an infinit Loop to get RDS Packets and Send them to subscribers
*
* RDS data will be available every 85 ms;
* Currently availability of RDS is checkes by tef665x_get_rds_status function
*
* @param rds_data_t : a rds message structure
* @return The JsonObject of latest rds info
*/
void *Get_RDS_Packets(rds_data_t *StuRDS){
pthread_detach(pthread_self());
uint32_t fd = 0;
int ret = i2c_init(I2C_DEV, _open, &fd);
uint8_t status[2];
ret=tef665x_get_rds_status(fd, status);
if(ret==1){
if(status[0]>7){
//RDS must update all the time, except the times we are scanning or changing frequency
//when scanning or changing frequncy, we unlock RDS_Mutex and it will end this thread
for (int ref_cnt=0; pthread_mutex_trylock(&RDS_Mutex) != 0;ref_cnt++){
//Get New RDS Data
tef665x_get_rds_data(fd,StuRDS);
//Send RDS Data after rexeiving 22 Packets
if(ref_cnt%22==0){
pthread_t t0;
pthread_create(&t0, NULL,Send_Rds_Result ,(void *) (&RDS_Message));
}
//Wait for 85ms before reading available rds data
usleep(85000);
}
pthread_mutex_unlock (&RDS_Mutex);
}
else{
AFB_ERROR("RDS is Not Valid0");
}
}
else{
AFB_ERROR("RDS is Not Valid1");
}
i2c_init(I2C_DEV, _close, &fd);
}
/*
* @brief Free Allocated Memory for Scan Thread and Unlock Scan Mutex
*
* @param scan_data : scan_data_t contains direction of search and callback
* for station_found event
*/
static void scan_cleanup_handler(void *scan_data)
{
pthread_mutex_unlock(&scan_mutex);
free(scan_data);
scanning=false;
}
/*
* @brief Create a loop to scan from current frequency to find a valid frequency
*
* If found a valid frequency, send station_found to subscribers and break the loop;
* If the direction was forward and reach the maximum frequency, Search Must continue
* from minimum frequency
* If the direction was backward and reach the minimum frequency, Search Must continue
* from maximum frequency
* If no valid frequency found, scan will stop at the begining point
* If stop_scan called, scan_mutex will be unlocked and thread must be stopped
*
* @param scan_data : scan_data_t contains direction of search and callback
* for station_found event
*/
void *scan_frequencies(scan_data_t* scan_data){
pthread_cleanup_push(scan_cleanup_handler, (void *)scan_data);
//Kill the thread when it was over
pthread_detach(pthread_self());
//Set Scan Flag
scanning=true;
//"Unlock Mutex" Flag
bool unlck_mtx = false;
uint32_t new_freq = 0;
uint32_t init_freq = 0;
init_freq = current_band == BAND_FM ? current_fm_frequency : current_am_frequency;
//First Mute Current Frequency
tef665x_search_frequency(init_freq);
//freq_step will be negative if direction was backward and positive if direction was forward
uint32_t freq_step = tef665x_get_frequency_step(current_band) * (scan_data->direction==SCAN_FORWARD?1:-1);
//Continue loop until reaching the initial frequency
while(init_freq != new_freq)
{
//Check Status of scan_mutex
unlck_mtx = pthread_mutex_trylock(&scan_mutex)==0;
//break the loop if scan_mutex was unlocked
if(unlck_mtx)
{
break;
}
if(current_band==BAND_FM)
{
new_freq = current_fm_frequency + freq_step;
//Searching Step is 100 KHz
//If frequency reached to initial point, the search must stop
while (((new_freq/10000)%10)!=0 && init_freq != new_freq){
new_freq = new_freq+freq_step;
}
}
else
{
new_freq = current_am_frequency + freq_step;
}
//Set Freq to min when it was more than Max Value
if(new_freq>tef665x_get_max_frequency(current_band))
{
new_freq=tef665x_get_min_frequency(current_band);
}
//Set Freq to max when it was less than Min Value
if(new_freq<tef665x_get_min_frequency(current_band))
{
new_freq=tef665x_get_max_frequency(current_band);
}
//Tune to new frequency
tef665x_search_frequency(new_freq);
//wait 30 ms to make sure quality data is available
for(int i=0;i<40;i++)
{
usleep(1000);
//Check scan_mutex lock for handling stop_scan
unlck_mtx=pthread_mutex_trylock(&scan_mutex)==0;
if(unlck_mtx)
{
break;
}
}
if(unlck_mtx)
{
break;
}
//Get Quality of tuned frequeency
tef665x_get_quality_info();//Get_quality_status();
if((quality.rssi >260 /*&& ->.usn<100/**/) || quality.bandw>1200)
{
//Send frequency value
if(scan_data->callback)
{
scan_data->callback(new_freq,NULL);
}
break;
}
usleep(100);
}
//Calling last pthread_cleanup_push
pthread_cleanup_pop(1);
}
/*
* @brief Get latest RDS Info and send rds jsonObject as response
*
* @return: cast rds_json(json_object) to (char *) and return result as response
*/
static char *tef665x_get_rds_info(void)
{
//If Getting RDS Result wasn't already started, Start it now
if(pthread_mutex_trylock(&RDS_Mutex) == 0)
{
AFB_DEBUG("Create the thread.");
pthread_create(&rds_thread, NULL,Get_RDS_Packets ,(void *) (&RDS_Message));
}
//Send latest available rds data
json_object *rds_json=(json_object *)Send_Rds_Result(&RDS_Message);
//Convert json_object to char* and send it as response
return (char *)json_object_to_json_string(rds_json);
}
/*
* @brief Get latest quality Info and send quality parameters as response
*
* module 32/33 FM/AM
* cmd 129 Get_Quality_Data
*
* index
* 1 status
* [ 15:0 ]
* quality detector status
* [15] = AF_update flag
* 0 = continuous quality data with time stamp
* 1 = AF_Update sampled data
* [14:10] = reserved
* 0 = no data loss
* 1 = previose data not read, replaced by newer data.
* [9:0] = quality time stamp
* 0 = tuning is in progress, no quality data available
* 1 … 320 (* 0.1 ms) = 0.1 … 32 ms after tuning,
* quality data available, reliability depending on time stamp
* 1000 = > 32 ms after tuning
* quality data continuously updated
*
* 2 level
* [ 15:0 ] (signed)
* level detector result
* -200 … 1200 (0.1 * dBuV) = -20 … 120 dBuV RF input level
* actual range and accuracy is limited by noise and agc
*
* 3 usn
* [ 15:0 ] = noise detector
* FM ultrasonic noise detector
* 0 … 1000 (*0.1 %) = 0 … 100% relative usn detector result
*
* 4 wam
* [ 15:0 ] = radio frequency offset
* FM ‘wideband-AM’ multipath detector
* 0 … 1000 (*0.1 %) = 0 … 100% relative wam detector result
*
* 5 offset
* [ 15:0 ] (signed) = radio frequency offset
* -1200 … 1200 (*0.1 kHz) = -120 kHz … 120 kHz radio frequency error
* actual range and accuracy is limited by noise and bandwidth
*
* 6 bandwidth
* [ 15:0 ] = IF bandwidth
* FM 560 … 3110 [*0.1 kHz] = IF bandwidth 56 … 311 kHz; narrow … wide
* AM 30 … 80 [*0.1 kHz] = IF bandwidth 3 … 8 kHz; narrow … wide
*
* 7 modulation
* [ 15:0 ] = modulation detector
* FM 0 … 1000 [*0.1 %] = 0 … 100% modulation = 0 … 75 kHz FM dev.
*
* @return: cast station_quality_t pointer as response
*
*/
static station_quality_t *tef665x_get_quality_info(void)
{
uint32_t i2c_file_desc=0;
uint8_t data[14];
int ret = i2c_init(I2C_DEV, _open, &i2c_file_desc);
if(current_band==BAND_FM)
{
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_FM,
TEF665X_Cmd_Get_Quality_Data,
data, sizeof(data));
}
else
{
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_AM,
TEF665X_Cmd_Get_Quality_Data,
data, sizeof(data));
}
i2c_init(I2C_DEV, _close, &i2c_file_desc);
quality.af_update = data[0]&0b10000000;
quality.time_stamp = ((data[0]&0b00000011)<<8 | data[1]);
quality.rssi = (data[2] << 8 | data[3] );
quality.usn = (data[4] << 8 | data[5] );
quality.bandw = (data[10]<< 8 | data[11]);
return &quality;
}
/*
* @brief Start Scan
*
* @param radio_scan_direction_t direction which is the scan direction and can be
* SCAN_FORWARD or SCAN_BACKWARD
* @param radio_scan_callback_t callback which is the callback for sending result of search to
* station_found ecent subscribers
* @return void
*/
static void tef665x_scan_start(radio_scan_direction_t direction,
radio_scan_callback_t callback,
void *data)
{
//Stop RDS if enabled
pthread_mutex_unlock (&RDS_Mutex);
//Stop current scan:
if(scanning)
{
tef665x_scan_stop();
}
scan_data_t *inputs;
//Clean RDS Message since frequency will change
Clear_RDS_Data(&RDS_Message);
usleep(10000);
AFB_DEBUG("check Mutex Condition");
//check if is there any activated search
if(pthread_mutex_trylock(&scan_mutex)==0&&!scanning)
{
AFB_DEBUG("Start Scanning...");
inputs=malloc(sizeof(*inputs));
if(!inputs)
return -ENOMEM;
inputs->direction= direction;
inputs->callback= callback;
inputs->data=data;
pthread_create(&scan_thread, NULL,scan_frequencies ,(void *) inputs);
}
}
/*
* @brief Stop Scan
*
* By unlocking scan_mutex, Scan thread will be stopped safely and update scanning flag
*
* @return void
*/
static void tef665x_scan_stop(void)
{
pthread_mutex_unlock(&scan_mutex);
while(scanning)
{
usleep(100);
AFB_DEBUG(" Wait for unlocking scan Thread");
}
}
/*
module 32 / 33 FM / AM
cmd 133 Get_Signal_Status | status
index
1 status
[ 15:0 ] = Radio signal information
[15] = 0 : mono signal
[15] = 1 : FM stereo signal (stereo pilot detected)
[14] = 0 : analog signal
[14] = 1 : digital signal (blend input activated by digital processor or control)
(TEF6659 only)
*/
radio_stereo_mode_t tef665x_get_stereo_mode(void)
{
uint32_t i2c_file_desc = 0;
int ret = i2c_init(I2C_DEV, _open, &i2c_file_desc);
uint8_t data[2];
if(current_band==BAND_FM){
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_FM,
TEF665X_Cmd_Get_Signal_Status,
data, sizeof(data));
}
else{
ret = tef665x_get_cmd(i2c_file_desc, TEF665X_MODULE_AM,
TEF665X_Cmd_Get_Signal_Status,
data, sizeof(data));
}
i2c_init(I2C_DEV, _close, &i2c_file_desc);
return data[0]>>7 ==1 ? STEREO:MONO;
}
static void tef665x_stop(void)
{
int ret;
GstEvent *event;
audio_set_mute(file_desc, 1);
if(present && running) {
// Stop pipeline
running = false;
ret = gst_element_set_state(pipeline, GST_STATE_PAUSED);
_debug("gst_element_set_state to pause", ret);
// Flush pipeline
// This seems required to avoidstatic stutters on starts after a stop
event = gst_event_new_flush_start();
gst_element_send_event(GST_ELEMENT(pipeline), event);
event = gst_event_new_flush_stop(TRUE);
gst_element_send_event(GST_ELEMENT(pipeline), event);
}
}
static int tef665x_init()
{
char gst_pipeline_str[GST_PIPELINE_LEN];
int rc;
current_am_frequency = known_am_band_plans[am_bandplan].min;
current_fm_frequency = known_fm_band_plans[fm_bandplan].min;
rc = i2c_init(I2C_DEV, _open, &file_desc);
if(rc < 0) {
AFB_NOTICE("tef665x not present");
return -1;
}
_debug("file_desc= ", file_desc);
rc = appl_get_identification(file_desc);
if(rc != 1){
AFB_ERROR("no tef665x!");
return -1;
}
current_band = BAND_AM;
radio_powerSwitch(file_desc, 1);
tef665x_chip_init(file_desc);
// Initialize GStreamer
gst_init(NULL, NULL);
// Use PipeWire output
// This pipeline is working on imx6solo, the important thing, up to now, is that it gets xrun error every few seconds.
// I believe it's related to wireplumber on imx6.
rc = snprintf(gst_pipeline_str,
GST_PIPELINE_LEN,
"alsasrc device=hw:1,0 ! audioconvert ! audioresample ! audio/x-raw, rate=48000, channels=2 \
! pwaudiosink stream-properties=\"p,media.role=Multimedia\" latency-time=35000");
if(rc >= GST_PIPELINE_LEN) {
AFB_ERROR("pipeline string too long");
return -1;
}
printf("pipeline: , %s\n", gst_pipeline_str);
pipeline = gst_parse_launch(gst_pipeline_str, NULL);
if(!pipeline) {
AFB_ERROR("pipeline construction failed!");
return -1;
}
// Start pipeline in paused state
rc = gst_element_set_state(pipeline, GST_STATE_PAUSED);
_debug("gst_element_set_state to pause (at the begining)", rc);
rc = gst_bus_add_watch(gst_element_get_bus(pipeline), (GstBusFunc) handle_message, NULL);
_debug("gst_bus_add_watch rc", rc);
present = true;
//Initialize Mutex Lock for Scan and RDS
pthread_mutex_init(&scan_mutex, NULL);
pthread_mutex_init (&RDS_Mutex, NULL);
tef665x_start();
return 0;
}
static void tef665x_set_frequency_callback(radio_freq_callback_t callback,
void *data)
{
freq_callback = callback;
freq_callback_data = data;
}
static void tef665x_set_rds_callback(radio_rds_callback_t callback)
{
rds_callback = callback;
}
static void tef665x_set_output(const char *output)
{
}
static radio_band_t tef665x_get_band(void)
{
_debug("band", current_band);
return current_band;
}
static void tef665x_set_band(radio_band_t band)
{
uint32_t fd = 0;
int ret = i2c_init(I2C_DEV, _open, &fd);
_debug("i2c_init ret value", ret);
if(band == BAND_FM){
current_band = band;
FM_tune_to(fd, eAR_TuningAction_Preset, current_fm_frequency / 10000);
} else {
current_band = band;
AM_tune_to(fd, eAR_TuningAction_Preset, current_am_frequency / 1000);
}
i2c_init(I2C_DEV, _close, &fd);
_debug("band", current_band);
}
static uint32_t tef665x_get_frequency(void)
{
if(current_band == BAND_FM){
return current_fm_frequency;
} else {
return current_am_frequency;
}
}
static void tef665x_set_alternative_frequency(uint32_t frequency)
{
uint32_t fd = 0;
int ret = i2c_init(I2C_DEV, _open, &fd);
if(current_band == BAND_FM)
{
FM_tune_to(fd, eAR_TuningAction_AF_Update, frequency / 10000);
}
i2c_init(I2C_DEV, _close, &fd);
}
static void tef665x_set_frequency(uint32_t frequency)
{
uint32_t fd = 0;
if(!present)
return;
if(scanning)
return;
if(current_band == BAND_FM) {
if(frequency < known_fm_band_plans[fm_bandplan].min ||
frequency > known_fm_band_plans[fm_bandplan].max ) {
_debug("invalid FM frequency", frequency);
return;
}
} else {
if(frequency < known_am_band_plans[am_bandplan].min ||
frequency > known_am_band_plans[am_bandplan].max ) {
_debug("invalid AM frequency", frequency);
return;
}
}
int ret = i2c_init(I2C_DEV, _open, &fd);
if(current_band == BAND_FM){
current_fm_frequency = frequency;
_debug("frequency set to FM :", frequency);
FM_tune_to(fd, eAR_TuningAction_Preset, frequency / 10000);
} else {
current_am_frequency = frequency;
_debug("frequency set to AM :", frequency);
AM_tune_to(fd, eAR_TuningAction_Preset, frequency / 1000);
}
i2c_init(I2C_DEV, _close, &fd);
//Send Frequency data to subscribers
if(freq_callback)
{
freq_callback(frequency, freq_callback_data);
}
//Start RDS if the band was FM
if(current_band==BAND_FM){
//Unlock Mutex
pthread_mutex_unlock (&RDS_Mutex);
//Clean RDS Message
Clear_RDS_Data(&RDS_Message);
//Wait to make sure rds thread is finished
usleep(300000);
//Restart RDS
tef665x_get_rds_info();
}
}
/*
* @brief Tune to a frequency in search mode
*
* Tune to new program and stay muted
* Sending new frequency to subscribers
*
* @param uint32_t which is the frequecy to be tuned
* @return void
*/
static void tef665x_search_frequency(uint32_t frequency)
{
uint32_t fd = 0;
int ret = i2c_init(I2C_DEV, _open, &fd);
if(current_band == BAND_FM)
{
current_fm_frequency = frequency;
_debug("frequency set to FM :", frequency);
FM_tune_to(fd, eAR_TuningAction_Search, frequency / 10000);
}
else
{
current_am_frequency = frequency;
_debug("frequency set to AM :", frequency);
AM_tune_to(fd, eAR_TuningAction_Search, frequency / 1000);
}
i2c_init(I2C_DEV, _close, &fd);
//Send Frequency data to subscribers
if(freq_callback)
{
freq_callback(frequency, freq_callback_data);
}
}
static int tef665x_band_supported(radio_band_t band)
{
if(band == BAND_FM || band == BAND_AM)
return 1;
return 0;
}
static uint32_t tef665x_get_min_frequency(radio_band_t band)
{
if(band == BAND_FM) {
return known_fm_band_plans[fm_bandplan].min;
} else {
return known_am_band_plans[am_bandplan].min;
}
}
static uint32_t tef665x_get_max_frequency(radio_band_t band)
{
if(band == BAND_FM) {
return known_fm_band_plans[fm_bandplan].max;
} else {
return known_am_band_plans[am_bandplan].max;
}
}
static uint32_t tef665x_get_frequency_step(radio_band_t band)
{
uint32_t ret = 0;
switch (band) {
case BAND_AM:
ret = known_am_band_plans[am_bandplan].step;
break;
case BAND_FM:
ret = known_fm_band_plans[fm_bandplan].step;
break;
default:
break;
}
return ret;
}
radio_impl_ops_t tef665x_impl_ops = {
.name = "TEF665x",
.init = tef665x_init,
.start = tef665x_start,
.stop = tef665x_stop,
.set_output = tef665x_set_output,
.get_frequency = tef665x_get_frequency,
.set_frequency = tef665x_set_frequency,
.set_frequency_callback = tef665x_set_frequency_callback,
.set_rds_callback=tef665x_set_rds_callback,
.get_band = tef665x_get_band,
.set_band = tef665x_set_band,
.band_supported = tef665x_band_supported,
.get_min_frequency = tef665x_get_min_frequency,
.get_max_frequency = tef665x_get_max_frequency,
.get_frequency_step = tef665x_get_frequency_step,
.scan_start = tef665x_scan_start,
.scan_stop = tef665x_scan_stop,
.get_stereo_mode = tef665x_get_stereo_mode,
//.set_stereo_mode = tef665x_set_stereo_mode,*/
.get_rds_info = tef665x_get_rds_info,
.get_quality_info = tef665x_get_quality_info,
.set_alternative_frequency = tef665x_set_alternative_frequency
};
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